Protein glycosylation, likely a sweet but dangerous coat on the cell surface, plays essential roles in cell-cell recognition, communication and adhesion in normal situation. However, aberrant glycosylation may result in many severe effects, such as cancer cell metastasis. Glycosylation process is a successive action of transferases, which cause the heterogeneity and uncertainty of glycan structures that may be attached to any glycosylation site. To resolve site-specific glycosylation pattern on glycoproteins is a considerable analytical challenge but is essential to provide the much needed structural details for functional studies. Experimental approach in which glycans are cleaved off may facilitate identification and sequencing of the deglycoslated peptide but information on the site-specific glycan is lost. With the development of proteomic technologies and mass spectrometers, multi-stage tandem mass spectrometry (MS) becomes an indispensible tool for glycosylation mapping. Two hyphenated mass spectrometers, Quadrupole/Time-of-flight (Q-TOF) and LTQ-Orbitrap, are the most common tools in proteomic field. The major aim of this thesis work was to develop a practical mass spectrometry-based platform for site-specific glycosylation mapping. For the single glycoprotein with known sequnce, Precursor ion discovery (PID) function on Waters Q-TOF system provided not only a simple way for glycopeptides scouting but also a reliable combination of glycan and peptide sequence in which information on peptide was derived from the prominent Y1 ion corresponding to the peptides core carrying an N-acetylglucosamine residue. For unknown proteins or glycoproteome, further sequencing of this peptide core is necessary. Two key techniques developed and presented here are both based on a general workflow of two sequential steps: 1) survey scouting of candidate glycopeptides or Y1 ions on the first survey, and 2) targeted multi-stage mass spectrometry for confirmation of peptide sequence. In Q-TOF system, LC-MSE provides a simple way for first survey of glycopeptides. Subsequently, the identified peptide sequences are validated by targeted pseudo-MS3, which can only be implemented on Q-TOF system equipped with dual-collision cells. The LTQ-Orbitrap mass spectrometer can provide a true MS3 function. However, the most critical consideration for glycopeptide sequencing is ability to correctly identify the right Y1 ion for MS3 analysis. Therefore, the first step of the workflow on LTQ-Orbitrap is to assign the accurate Y1 ion from HCD (higher collision energy dissociation), followed by a targeted MS3 analysis. These two-tier workflows established were first validated by using the single well-known glycoprotein standard, fetuin. Then, the origin of unexpected proteolytic glycopeptides from the purified glycoprotein with O-acetylated disialylated N-glycan from snake venom was confirmed by both methods. For real glycoproteomic studies, the glycopeptides from two biological materials, the serum and a cancer cell line, were enriched according to its respective glycosylation profile and successfully analyzed by each MS method. The protein identities and glycan composition of most glycosylated proteins were confirmed in both cases. Finally, for sample of highest complexity, i.e. an intact fertilized zebrafish eggs, both MS3 approaches were used for more comprehensive glycoproteomic analysis. To better understand the developmental glycobiology of this important model, it is imperative to delineate the spatial-temporal distribution of the different classes of glycans and their respective protein carriers. Large amount of endogenously digested O-glycopeptides were only observed in the chorion/perivitelline compartment but not the yolk or embryos. From the latter fractions, vitellogenin was identified as the protein carrier of the unique complex type N-glycan structures.